JP2014238255A - Moisture separator configuration - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a moisture separator with increased effectiveness compared to prior art moisture separators.SOLUTION: There is provided a moisture separator configuration 10 for separating water droplets from steam of a flow 20 comprising a mixture of steam and water droplets. The cited flow 20 passes through the moisture separator configuration 10 so that this separation is achieved. The moisture separator configuration 10 comprises a plurality of plates 11 oriented in parallel with the flow 20. The plurality of plates 11 form channels 30 though which the flow 20 passes. The channels 30 have progressive cross section variation along the flow 20 direction in order to collect progressively the water droplets separated from the steam in the flow 20.

Description

  The present invention relates to a moisture separator configuration that provides enhanced effectiveness, particularly for use in power plants.

A moisture separator, also known as a droplet separator, is a device for separating water droplets from steam. Moisture separators are widely used in the oil and gas industry to remove droplets from gas or vapor. In general, mist removal is necessary for several reasons, as described below.
• One reason is to increase the cycle efficiency of the power plant. Normally, in a thermal power plant, steam generated from a boiler is expanded a plurality of times in a so-called high pressure turbine (HPT), medium pressure turbine (MPT) and low pressure turbine (LPT). In a nuclear power plant, nucleation occurs along the HPT cylinder during the first expansion in the HPT of superheated or saturated steam sent from the boiler, and the resulting working fluid in the HPT exhaust is a predetermined steam Wet steam with quality. Prior to reheating wet steam upstream of MPT and LPT for efficiency reasons, mechanical separation of moisture from saturated steam is performed by a moisture separator: the resulting sent to the reheater bundle The working fluid is wet steam with a low moisture content. Since the latent heat of water evaporation is significantly higher, it is preferable to eliminate moisture in the wet steam and send the collected water back in the thermodynamic cycle instead of using a lot of energy for moisture evaporation. It also limits the heat load in the bundle that is generated by the.
Another benefit achieved by removing moisture content is the protection of downstream equipment from corrosion damage. One type of moisture separator is a so-called corrugated plate mist eliminator widely used in the oil and gas industry as well as in the power generation industry to remove droplets from the gas or vapor phase. Most separators make use of the principle of inertia, whereby large drops of water continue to move more linearly when the direction of the air / steam flow flow in which these drops are carried is changed. Try to. These wave side plate mist eliminators include a plurality of closely spaced corrugated bent metal sheets oriented parallel to the air / steam flow path. A two-phase flow (a mixture of steam and water droplets) is forced through a tortuous channel and the flow direction is repeatedly changed. Water droplets that cannot follow such a change of direction due to inertia deviate from the main flow, collide with the channel wall, and adhere to and aggregate on the wall. If the amount of liquid is large enough, a membrane and liquid trickle are formed, which are continuously drained from the corrugated plate mist eliminator by gravity. Droplet inertia and vapor drag control droplet movement through the channel.

  The present invention relates to a moisture separator that is more effective than prior art moisture separators.

  The present invention relates to a moisture separator configuration, particularly used in power plants. The moisture separator configuration comprises a plurality of plates, preferably a plurality of metal sheets bent into corrugations, which plates contain gas / vapors and water droplets and pass through the cited moisture separator configuration. Directed parallel to the flow so that the water droplets are effectively separated from the vapor after passing through the flowed moisture separator configuration. Water droplets separated from the vapor are collected on the plate wall, thereby forming a liquid film or trickle when the amount of these water droplets is sufficiently large, which are then drained from the plate by gravity. .

The moisture separator configuration of the present invention has the following characteristics:
Each plate has a non-collision wall side and a collision wall side, the non-collision wall side having a smooth surface, whereas the collision wall side reduces the existing film thickness and thus the critical gas / vapor velocity A plurality of longitudinal grooves that constitute a plurality of discharge channels to reduce the risk of re-scattering and to help discharge the liquid film accumulated on the plate wall.
-The coupling of each plate pair forms a venturi channel aimed at preventing the respraying effect due to vapor streamline separation / dissociation from the plate wall.
-The coupling of each plate pair constitutes a first concave cavity to capture the deposited water droplets and prevent direct exposure to high / vapor flow rates.
The second concave cavity is at the end of the plate in the moisture separator configuration to capture water droplets that have not yet been captured by the first concave cavity and to separate them from the vapor. It is configured.
The wall step when the two plates are brought together at the end of the moisture separator arrangement to isolate the water film from the action of shear forces applied by steam in the region where the wall step is formed Is also configured.
-An intermediate region with increased turbulent dispersion is formed to increase the separation of the small water droplets that remain and not yet collected and to separate these small water droplets from the vapor.
A plurality of window openings are formed in the plate, these window openings form passages for the steam and at the same time act as a structural device, preventing vibrations in the moisture separator configuration;

  Thus, a moisture separator configuration according to the present invention can provide a retention system with high effectiveness, and gradual water droplet collection is achieved.

  Many of the problems and attendant advantages of the present invention will be more readily appreciated. This is because they are further understood by reference to the following detailed description when viewed in conjunction with the accompanying drawings.

FIG. 3 is a plan view of a moisture separator configuration that provides enhanced effectiveness in accordance with the present invention. FIG. 5 is a side view of a moisture separator configuration that provides enhanced effectiveness in accordance with the present invention. FIG. 6 is a bottom view of a moisture separator configuration that provides enhanced effectiveness in accordance with the present invention.

  The present invention relates to a moisture separator arrangement 10 comprising a plurality of plates 11, preferably a plurality of metal sheets bent into a corrugation, as shown in either FIG. 1, FIG. 2 or FIG. The plurality of plates 11 form channels 30 through which the flow 20 is guided: the plates 11 are directed parallel to the flow 20 passing through the cited moisture separator configuration 10. This stream 20 contains a mixture of steam and water droplets. The water droplets are separated from the vapor while passing through the flowed moisture separator arrangement 10. When the amount of water droplets collected on the wall of the plate 11 becomes sufficiently large, a liquid film is formed, and this liquid film is then drained from the plate 11 by gravity. Each plate 11 in the moisture separator configuration 10 has a non-collision wall side 12 and a collision wall side 13, the non-collision wall side 12 has a smooth surface, and the collision wall side 13 has a plurality of longitudinal lengths. These longitudinal grooves 14 help to drain the water droplets collected on the plate walls, reduce the average wall thickness, and thus reduce the effect of shear forces, and consequently A plurality of discharge channels 60 are formed for separating steam from the water film by reducing the water drag acting at the level of the steam / water film interface. Each pair of couplings of plates 11 and 11 ′ (see FIG. 2) forms a venturi channel 40, which separates the streamline from the wall profile induced by the reverse pressure gradient. / Prevent re-scattering effect due to dissociation. In addition, each pair of couplings of plates 11 and 11 ′ also forms a first concave cavity 104 to catch water drops and prevent water film transport on the non-impact wall side 12. Yes.

  Each plate 11 has a smooth non-collision wall side 12, while the other side has a longitudinal groove 14 on the collision wall side 13. These longitudinal grooves 14 are provided to help drain water drops collected from the stream 20, thereby preventing / limiting water film drag. Since the impact wall side 13 of each plate 11 of the plate 11 having the drainage channel 60 has a tendency to redirect the transport steam in the flow 20 as it passes through the channel 30 almost collides with the impact wall side 13 of the plate 11. Displace water droplets.

The discharge channel 60 has three functions:
a) When the water film enters the drainage channel 60, it reduces the interfacial shear force acting on the water film surface (between the transport medium stream 20 and the water film) and at the outlet of the moisture separator arrangement 10 Avoid as much water film transport as possible.
b) The accumulation of water itself in the drainage channel 60 increases the gravity of the water and aids drainage.
c) Reduce the average wall thickness.

  The coupling of the two plates 11 and 11 'results in a kind of venturi channel 40 and a first concave cavity 104 intended to capture the collected water on the non-impact wall side. The venturi channel 40 sucks a water film inside the venturi itself (to avoid choking in front of the venturi channel) and at the same time known as resplash in the literature for this type of corrugated plate moisture separator. The effect is to avoid water film dissociation from the collision wall side 13 of the plate 11 due to turbulent flow separation of the transport medium (flow 20) that occurs immediately after the curvature of the plate 11 corresponding to the inlet of the venturi channel 40. Objective. On the opposite side of the venturi channel 40, the initial width of the channel 30 has been reduced due to the space occupied by the venturi itself, due to the reduction in the cross-section of the remainder of the channel 30 due to window opening and bending of the channel 30. The remaining water droplets in stream 20 are accelerated and these water droplets cannot follow a strong change in the direction of flow 20 (carrying medium), so that these water droplets impinge on the non-collision wall side 12 of plate 11. This forms a water film that is collected and drained by the first concave cavity 104.

  The moisture separator configuration 10 of the present invention has not yet been captured by the first concave cavity 104 to drain the water film transported out of the venturi channel 40, if not already drained. It has at least a second concave cavity 103 configured at the end of the plate 11 to capture the water drops and separate them from the vapor (FIG. 2). In addition, two plates 11 and 11 ′ are aligned at the end of the moisture separator configuration 10 to isolate the water film from the action of shear forces applied by steam in the region where the wall step 102 is formed. When this is done, the wall step 102 is also configured.

  FIG. 2 shows an intermediate region 101 with increased turbulent dispersion, which is configured to increase the collection of small droplets that remain and have not yet been collected. These small water droplets are separated from the vapor in stream 20.

  The moisture separator configuration 10 of the present invention acts as a structural device while forming a passage to the flow 20 and forms a channel 30 to prevent vibrations in the moisture separation configuration 10 (FIG. 3).

In general, moisture separators are used in marine gas turbines and industrial applications. At the power plant, mist removal is necessary for several reasons:
One reason is to increase the cycle efficiency of power plants that handle thermal cycles where steam is expanded multiple times by HPT (high pressure turbine), MPT and LPT (medium and low pressure turbines) After being subjected to a reheat process to increase its enthalpy before being processed by the next turbine. Since the latent heat of evaporation is quite high, the moisture content of the wet steam is mechanically separated instead of being removed by the evaporation process.
-Another advantage achieved by removing moisture content is the protection of downstream equipment from corrosion damage.

The main advantages of the moisture separator configuration 10 of the present invention over known configurations in the prior art are as follows:
-Higher dynamic pressure for re-spraying effect-Higher plates and consequently fewer components are needed to collect water at the bottom of the separator plate (gutter)-More in terms of steam direction Short plate-modularity.

  Although the present invention has been described fully in terms of preferred embodiments, modifications may be made to the scope of the invention, and the invention is not considered to be limited by these embodiments, but the following claims According to the contents of the section.

10 Moisture separator configuration 11, 11 'plate 20 Flow (flow and water droplets)
30 Channel 12 Plate non-impact wall side 13 Plate impact wall side 14 Longitudinal groove 40 Venturi channel 101 Intermediate region with increased turbulent dispersion 102 Wall step 103 Second concave cavity 104 First concave shape Cavity 60 Drain channel 70 Window opening

Claims (10)

A moisture separator arrangement (10) for separating water droplets from steam of a stream (20) comprising a mixture of steam and water droplets, wherein the cited stream (20) is moistened so that this separation is achieved. A moisture separator configuration (10) having a plurality of plates (11) that pass through the separator configuration (10) and oriented parallel to the flow (20). In
The plurality of plates (11) form channels (30) through which the flow (20) passes, and the channels (30) pass through the flow (20). ) From a stream of steam comprising a mixture of steam and water droplets, characterized by having a gradual cross-sectional change along the direction of the stream (20) to gradually collect the water drops separated from the steam in Moisture separator configuration (10) for separating water droplets.   The moisture separator arrangement (10) of claim 1, wherein the plurality of plates (11) comprises a plurality of sheets bent into a corrugation.   The channel (30) is configured such that an intermediate region (101) is formed where the flow (20) is exposed to increased turbulent dispersion to increase the collection of small water droplets from the vapor. A moisture separator arrangement (10) according to claim 2, wherein:   Each one of the plurality of plates (11) has, on one of its wall sides (13), a plurality of longitudinal grooves (14) that form a plurality of drainage channels (60). The moisture separator configuration (10) according to any one of claims 1 to 3, wherein a water film transport due to an interfacial vapor / water film shear stress effect is avoided.   The coupling of each pair of the plates (11, 11 ′) constitutes a venturi channel (40), which helps the vapor streamlines not dissociate from the impingement wall, thereby The moisture separator configuration (10) according to any one of claims 1 to 4, wherein the effect of re-scattering on the wall side is prevented.   The coupling of each pair of the plates (11, 11 ′) captures small water droplets, separates the water droplets from the vapor in the stream (20), and the water film collected on this side of the channel is carried over. 6. A moisture separator arrangement (10) according to any one of the preceding claims, comprising a first concave cavity (104) to prevent this.   The second concave cavity (103) to capture water droplets that have not yet been captured by the first concave cavity (104) and prevent the water film collected on this side of the channel from being carried over. A moisture separator (10) according to claim 6, characterized in that is configured at the end of the plate (11).   Two plates (11 and 11 ′) at the end of the moisture separator configuration (10) to isolate the water film from the action of shear forces applied by steam in the region where the wall step (102) is formed. 8. The moisture separator configuration (10) according to claim 1, wherein the wall step (102) is also configured when the two are combined.   The plate (11 ') each has a plurality of window openings (70) forming passages for the flow (20) to prevent vibrations in the moisture separator configuration (10). A moisture separator configuration (10) according to any one of claims 1 to 8.   A heat exchanger comprising a moisture separator configuration (10) according to any one of claims 1-9.

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